FI60945C - FJAEDERPACKE FOER ELEKTROMAGNETISKT RELAE - Google Patents

Description

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5¾¾¾ C (45) Patent nyämiolty 13 04 1932, ¾¾¾ Patent meddelat (51) Kv.lk.3 / lnt.C! .3 H 01 H 50/56 FINLAND —FINLAND (21) P »** nttlh» li * nHi * - Pstanuntdknlng 760938 (22) HakamlspUvl - AmBknlngtdag 07.01 + .76 "(23) Alkuplivt — Glltighaudtg 07.0 ^ .76 (41) Become Public - Bllvlt offuntllg 08.10.76

Patent and Registration Office .... ., .

. _. (44) Nlhtlvlkslpenoo Ja kuul.Julkalsun pvm. - n oc ^ pagwterstyrelsen Ansökan utlagd och utl.skrlftan publtcarad 31 · 12.8l (32) (33) (31) Privilege requested —Begird prlorltet OJ .Ok .75 USSR (SU) 2122529 (71) (72) Iosif Semenovich Cherny, ulitsa Zemovaya, 6/1 sq. m. 85, Kharkov,

Mikhail Vasilievich Mischenko, ulitsa Kirgizskaya, 5a, kv. 3,

This invention relates to electromagnetic relays and in particular to parts of contact spring assemblies in electromagnetic relays. The present invention can be used in electromagnetic relays with multiple contact groups for connection.

Various contact spring constructions for electromagnetic relays are already known, in which each row of contact springs is already filled with an insulating agent in a compression mold in advance.

Such a technical method is not acceptable for the design of electromagnetic relays with coils where the contact parts are rigid shock-absorbing springs and flexible contact springs, because the plastic material tends to Virumaa under the flexible spring. In this case, cleaning the hull takes more time than assembling the entire stack.

Several patents are already known which use grooved plates as an insulating material and the springs are attached to these grooves by various methods. The simplest and most inventive in this series is a device equipped with guide projections for shock-absorbing springs that fit into these slots in a plastic frame. Such a structure can be used in relays with only plastic housings. The compressive force to prevent the springs from turning in their grooves is provided by a screw. The main disadvantage of such a structure is that the forced compression of the pack by means of a screw is constantly associated with the formation of small chips when the screw is screwed into the frame.

The frost structures of the contact springs for electromagnetic relays are already known, where the contact springs are fastened by means of projections around the edge of the insulating plates. In addition, such structures are provided with pieces which fit these contact parts. Such a structure allows longitudinal movements of the contact springs to be omitted. The disadvantage is that its assembly cannot be automated because it is necessary to precisely align the insulating plates and the parts of the contact springs with each other.

As a prototype, the electromagnetic relay has a packing structure comprising metal fasteners, contact springs placed between them and insulated from each other by plates made of thermoplastic material, in addition to a fitting passing through openings made in these fasteners and plates and connecting all components pack together.

Each contact spring is provided with two holes and each of the insulating plates is provided with two pieces that fit into the holes in the contact springs for assembly. During assembly of this pack and before its parts are assembled, the contact springs and plates are covered with a liquid thermosetting agent using a special applicator. After joining and fixing, the ends of this pack are riveted together and the pack is placed in an oven and heat treated. The fundamental disadvantage of this prototype is that: - the contact springs have to be made with two slots and therefore the axes of these slots have to be matched when the contact spring is attached to the plate, - the holes in the contact springs and the insulating plates cannot be connected to each other. use glue and heat treatment.

As a result, assembling this pack is a fairly labor intensive task.

The object of the present invention is to provide a friction structure of a relay contact spring which is much less labor intensive when assembling it.

These and other objects of the invention are realized in that in a structure of a pack of contact springs consisting of metal fasteners, the contact springs interposed therebetween are insulated from each other by plates made of thermoplastic material and a fitting passing through holes in these fasteners and plates, and connecting all parts of the pack together, in accordance with the present invention each thermoplastic sheet is provided with projections extending over the entire length of the surface facing the contact springs and the height of the springs is selected so that when the pack is compressed during assembly the contact springs are pressed between these projections until they come into contact with the surface of the plates.

The idea of the present invention consists in that the thermoplastic plates are provided with projections extending over the entire length of their surface facing the contact springs, the height of these projections being selected so as to ensure that the contact springs are compressed in these projections when the package is assembled until they are assembled. contacts with the surface of the plates and reliable connection of all parts in this pack is effected by each contact spring forming a single "lock" on the surface of the projections, which prevents the relative movement of its components.

It is preferred that the height of the protrusions is less than half the thickness of the contact springs. Such a height ensures the formation of a "lock" on the surface of the projections from two adjacent plates between which the contact spring is placed, this means that a "lock" of two core parts is formed with certainty and the reliability of assembling all components of the pack is increased.

If the height of the protrusions is made greater than half the thickness of the contact spring, these protrusions tend to close during assembly and the spring to be assembled in these protrusions does not come into contact with the plate and remains detached, making "locking" unreliable.

The present invention will now be described in more detail with reference to a particular embodiment and the accompanying drawings, in which: Figure 1 is a cross-sectional view of a spring pack according to the present invention.

Figure 2 shows a view taken along line II-II in Figure 1.

Figure 3 shows an axonometric view of some of the components of the stack (a, b, c, d, e, f) arranged as they are placed in the stack.

The packing structure of the contact springs consists of metal brackets 1 and 2 (Figures 1 and 2) and contact springs 3 and 4 interposed therebetween.

4,60945

The contact springs 3 and 4 are separated from each other by plates 5-7, which are made of a thermoplastic material.

Fasteners 1-2 and plates 5-7 are provided with holes 8 (Figure 3), 9-11 being made in the center of these fasteners and plates. The pack also includes a fitting 12 that passes through these holes and connects all components from the pack together.

The bracket 1 is a metal corner piece with a hole 8 in the middle. The diameter of the hole 8 is larger than the diagonal outside the fitting 12. The inner surface of the hole 8 is vaulted to fit the curved end of the fitting 12.

The bracket 2 is a flat metal plate with a hole 9 in the middle. The size and shape of the hole 9 are identical to the size and shape of the hole 8 in the corner bracket 1.

Contact springs 3-4 consist of flexible contact springs and rigid shock-absorbing springs welded to the pile before assembly. The springs 4 are longer than the springs 3. The longer arms of the springs 4 are intended to co-operate with the contact switching equipment in the electromagnetic relay (not shown).

Plates 5-7 made of thermoplastic material are rectangular and provided with holes 10-11 in the middle. The diameter of their holes is equal to the diameter of holes 8-9. The thickness of the plates may vary depending on the peculiarities of the structure of each pack.

The fitting 12 is a thin-walled metal tube, one end of which is pre-fitted with a bead.

According to the present invention, each plate 5-7 is provided with protrusions 13 (Fig. 3) extending over the entire length of their surface facing the contact springs 3-4. The plates 5 are provided with these projections 13 on their other surface. The other side of the plates 5 in contact with the solids 1-2 in the assembled stack is smooth. Plates 6-7 have protrusions on both sides. At least two protrusions should be provided on each side of each of the plates 5-7. It is not advantageous to provide three or more projections on each side of the plate because their number is proportional to the force of compression in the contact springs while the reliability of the "locking" remains the same.

The height of the protrusions 13 is selected so that when the pack is assembled for stacking, the contact springs 3-4 are compressed into the protrusions until they come into contact with the surface of the plates 5-7. The height of the projections 13 is less than half the thickness of the contact springs 3-4.

60945 5 Such a height ensures the formation of a "lock" on the surfaces of the projections of two adjacent plates, between which plates the contact spring is placed.

The pack is assembled as follows (as shown in Figure 3). The parts are placed in the assembly device (not shown) in the following order: angle bracket 1 and fitting 12 (Fig. 3a), plate 5 (Fig. 3b), two springs 3, plate 6 (Fig. 3c), two springs 4, plate 6, two spring 3 (Fig. 3d), plate 7 (not shown), two springs 3, plate 6, two springs 4, plate 6, two springs 3, plate 5 (Fig. 3e) and a bracket 2.

The pack is then compressed by the above-mentioned device acting on the bracket 2. All the contact springs 3 and 4 are pressed into the projections 13 in each adjacent plate 5-7 until they come into contact with the surface of the respective plates, thus forming a reliable "lock" for each contact spring. -7 compared. Once the pack is thus compressed into a pile, the end of the fitting 12 is riveted to the bracket and the fully assembled pack is removed from the assembly device.

The structure of this pack ensures that all components are reliably attached to each other. The efficiency of assembly increases significantly because, firstly, the components do not need to be precisely aligned with each other, secondly, there is no need to use glue and heat treatment, and thirdly, the assembly of some components can be mechanized and the compression of the pack can be automated.